| 4255817 | Heat insulative material articles comprising aramid fibers | 1981-03-17 | Heim | 428/920 |
| 4246313 | Heat-resistant composite material and method of making same | 1981-01-20 | Stengle | 428/920 |
| 4244994 | Laminated aramid fiber friction members | 1981-01-13 | Tramor et al. | 428/227 |
| 4228207 | Three-dimensional shaped articles | 1980-10-14 | Porte et al. | 428/902 |
| 4143197 | Aramid yarn fabrics and method of dimensional stabilization of same by heat setting | 1979-03-06 | Jasionowicz et al. | 428/225 |
It is well known that safety requirements require the removal of asbestos and asbestos products from industrial environments. Because of its heat resistant properties, asbestos has heretofore been the customarily used material of fabrication for products designed to resist the temperatures experienced in the handling and conveying of materials in the manufacture of glass products. The extreme temperature range normally is from about 1000° F. to about 1400° F. In many prior asbestos applications, a heat resistant material must be provided in the form of a fabric, such as for example (1) tractor pads, continuous belts, roller guide covers, reject belts and back stops in glass tube draw apparatus, (2) rotary scoop liners, divider covers, lehr loader conveyor belts in glass ribbon machines, (3) conveyor belts and cooling towers for glass pressware and (4) push pads which prevent checking and damage to the glass products.
It has unexpectedly been discovered that fabric constructed of yarns comprising (1) a ply constituting a minor amount of the fabric yarn and composed of aramide fiber and (2) a ply constituting a major amount of the fabric yarn and composed of glass filaments which fabric is a satisfactory replacement for asbestos fabric in heat resistant applications.
Yarns and fabrics constructed from continuous glass fibers are known and are known to have excellent heat resistant properties because of their inorganic nature. However, being composed entirely of glass introduces limitations on the uses of such products because of brittleness and the accompanying modulus of elasticity.
In certain heat resistant applications, yarns and fabrics constructed from aramide fibers have been found acceptable and such products have increased wearing ability and are more elastic than comparable materials manufactured from glass fibers. Increasing temperatures, however, are known to decrease the tensile properties of aramide fibers, and such fibers begin to char at temperatures between 800° F. and 900° F.
When a yarn ply composed of spun aramide fibers is plied with a yarn ply composed of continuous glass fibers, a composite yarn is formed which may be readily fabricated into textile materials having such superior thermal resistance and long life as to constitue an excellent replacement for comparable asbestos products.
A heat resistant fabric is prepared as follows: A single strand of 4/2's (cotton count) spun aramide fiber is twisted together with a single strand of 6.75 ETG textured glass filaments to form a plied yarn. A one-quarter inch thick, three inch wide fabric is formed from this yarn by weaving as follows:
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| Warp Ends- Ground system 266 ends Binder system 32 ends Filling yarns 14 per inch |
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In the finished fabric the aramide fiber constitutes 35 percent by weight of the yarn and the glass filaments constitute 65 percent by weight of the yarn.
This fabric sustains repeated contact with materials having temperatures of up to 1400° F. without melting, burning or losing its textile properties.
Fabrics made in accordance with the construction of this invention are suitably formed into continuous conveyor belting and have withstood daily exposure to contact operating temperatures in glass container production of from 1200°-1400° F. while exhibiting good resistance up to 60 days to wear and abrasion. This constitutes a satisfactory replacement for a comparable asbestos fabric.
The fabrics of this invention may suitably be impregnated with resin emulsions in order to enhance such properties as abrasion and hand.